/* 
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to You under the Apache License, Version 2.0
 * (the "License"); you may not use this file except in compliance with
 * the License.  You may obtain a copy of the License at
 * 
 * http://www.apache.org/licenses/LICENSE-2.0
 * 
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

using System;

namespace Lucene.Net.Util
{
	// from org.apache.solr.util rev 555343
	
	/// <summary>A variety of high efficiencly bit twiddling routines.
	/// 
	/// </summary>
	/// <version>  $Id$
	/// </version>
	public class BitUtil
	{
		
		/// <summary>Returns the number of bits set in the long </summary>
		public static int Pop(long x)
		{
			/* Hacker's Delight 32 bit pop function:
			* http://www.hackersdelight.org/HDcode/newCode/pop_arrayHS.cc
			*
			int pop(unsigned x) {
			x = x - ((x >> 1) & 0x55555555);
			x = (x & 0x33333333) + ((x >> 2) & 0x33333333);
			x = (x + (x >> 4)) & 0x0F0F0F0F;
			x = x + (x >> 8);
			x = x + (x >> 16);
			return x & 0x0000003F;
			}
			***/
			
			// 64 bit java version of the C function from above
			x = x - ((SupportClass.Number.URShift(x, 1)) & 0x5555555555555555L);
			x = (x & 0x3333333333333333L) + ((SupportClass.Number.URShift(x, 2)) & 0x3333333333333333L);
			x = (x + (SupportClass.Number.URShift(x, 4))) & 0x0F0F0F0F0F0F0F0FL;
			x = x + (SupportClass.Number.URShift(x, 8));
			x = x + (SupportClass.Number.URShift(x, 16));
			x = x + (SupportClass.Number.URShift(x, 32));
			return ((int) x) & 0x7F;
		}
		
		/// <summary> Returns the number of set bits in an array of longs. </summary>
		public static long Pop_array(long[] A, int wordOffset, int numWords)
		{
			/*
			* Robert Harley and David Seal's bit counting algorithm, as documented
			* in the revisions of Hacker's Delight
			* http://www.hackersdelight.org/revisions.pdf
			* http://www.hackersdelight.org/HDcode/newCode/pop_arrayHS.cc
			*
			* This function was adapted to Java, and extended to use 64 bit words.
			* if only we had access to wider registers like SSE from java...
			*
			* This function can be transformed to compute the popcount of other functions
			* on bitsets via something like this:
			* sed 's/A\[\([^]]*\)\]/\(A[\1] \& B[\1]\)/g'
			*
			*/
			int n = wordOffset + numWords;
			long tot = 0, tot8 = 0;
			long ones = 0, twos = 0, fours = 0;
			
			int i;
			for (i = wordOffset; i <= n - 8; i += 8)
			{
				/***  C macro from Hacker's Delight
				#define CSA(h,l, a,b,c) \
				{unsigned u = a ^ b; unsigned v = c; \
				h = (a & b) | (u & v); l = u ^ v;}
				***/
				
				long twosA, twosB, foursA, foursB, eights;
				
				// CSA(twosA, ones, ones, A[i], A[i+1])
				{
					long b = A[i], c = A[i + 1];
					long u = ones ^ b;
					twosA = (ones & b) | (u & c);
					ones = u ^ c;
				}
				// CSA(twosB, ones, ones, A[i+2], A[i+3])
				{
					long b = A[i + 2], c = A[i + 3];
					long u = ones ^ b;
					twosB = (ones & b) | (u & c);
					ones = u ^ c;
				}
				//CSA(foursA, twos, twos, twosA, twosB)
				{
					long u = twos ^ twosA;
					foursA = (twos & twosA) | (u & twosB);
					twos = u ^ twosB;
				}
				//CSA(twosA, ones, ones, A[i+4], A[i+5])
				{
					long b = A[i + 4], c = A[i + 5];
					long u = ones ^ b;
					twosA = (ones & b) | (u & c);
					ones = u ^ c;
				}
				// CSA(twosB, ones, ones, A[i+6], A[i+7])
				{
					long b = A[i + 6], c = A[i + 7];
					long u = ones ^ b;
					twosB = (ones & b) | (u & c);
					ones = u ^ c;
				}
				//CSA(foursB, twos, twos, twosA, twosB)
				{
					long u = twos ^ twosA;
					foursB = (twos & twosA) | (u & twosB);
					twos = u ^ twosB;
				}
				
				//CSA(eights, fours, fours, foursA, foursB)
				{
					long u = fours ^ foursA;
					eights = (fours & foursA) | (u & foursB);
					fours = u ^ foursB;
				}
				tot8 += Pop(eights);
			}
			
			// handle trailing words in a binary-search manner...
			// derived from the loop above by setting specific elements to 0.
			// the original method in Hackers Delight used a simple for loop:
			//   for (i = i; i < n; i++)      // Add in the last elements
			//  tot = tot + pop(A[i]);
			
			if (i <= n - 4)
			{
				long twosA, twosB, foursA, eights;
				{
					long b = A[i], c = A[i + 1];
					long u = ones ^ b;
					twosA = (ones & b) | (u & c);
					ones = u ^ c;
				}
				{
					long b = A[i + 2], c = A[i + 3];
					long u = ones ^ b;
					twosB = (ones & b) | (u & c);
					ones = u ^ c;
				}
				{
					long u = twos ^ twosA;
					foursA = (twos & twosA) | (u & twosB);
					twos = u ^ twosB;
				}
				eights = fours & foursA;
				fours = fours ^ foursA;
				
				tot8 += Pop(eights);
				i += 4;
			}
			
			if (i <= n - 2)
			{
				long b = A[i], c = A[i + 1];
				long u = ones ^ b;
				long twosA = (ones & b) | (u & c);
				ones = u ^ c;
				
				long foursA = twos & twosA;
				twos = twos ^ twosA;
				
				long eights = fours & foursA;
				fours = fours ^ foursA;
				
				tot8 += Pop(eights);
				i += 2;
			}
			
			if (i < n)
			{
				tot += Pop(A[i]);
			}
			
			tot += (Pop(fours) << 2) + (Pop(twos) << 1) + Pop(ones) + (tot8 << 3);
			
			return tot;
		}
		
		/// <summary>Returns the popcount or cardinality of the two sets after an intersection.
		/// Neither array is modified.
		/// </summary>
		public static long Pop_intersect(long[] A, long[] B, int wordOffset, int numWords)
		{
			// generated from pop_array via sed 's/A\[\([^]]*\)\]/\(A[\1] \& B[\1]\)/g'
			int n = wordOffset + numWords;
			long tot = 0, tot8 = 0;
			long ones = 0, twos = 0, fours = 0;
			
			int i;
			for (i = wordOffset; i <= n - 8; i += 8)
			{
				long twosA, twosB, foursA, foursB, eights;
				
				// CSA(twosA, ones, ones, (A[i] & B[i]), (A[i+1] & B[i+1]))
				{
					long b = (A[i] & B[i]), c = (A[i + 1] & B[i + 1]);
					long u = ones ^ b;
					twosA = (ones & b) | (u & c);
					ones = u ^ c;
				}
				// CSA(twosB, ones, ones, (A[i+2] & B[i+2]), (A[i+3] & B[i+3]))
				{
					long b = (A[i + 2] & B[i + 2]), c = (A[i + 3] & B[i + 3]);
					long u = ones ^ b;
					twosB = (ones & b) | (u & c);
					ones = u ^ c;
				}
				//CSA(foursA, twos, twos, twosA, twosB)
				{
					long u = twos ^ twosA;
					foursA = (twos & twosA) | (u & twosB);
					twos = u ^ twosB;
				}
				//CSA(twosA, ones, ones, (A[i+4] & B[i+4]), (A[i+5] & B[i+5]))
				{
					long b = (A[i + 4] & B[i + 4]), c = (A[i + 5] & B[i + 5]);
					long u = ones ^ b;
					twosA = (ones & b) | (u & c);
					ones = u ^ c;
				}
				// CSA(twosB, ones, ones, (A[i+6] & B[i+6]), (A[i+7] & B[i+7]))
				{
					long b = (A[i + 6] & B[i + 6]), c = (A[i + 7] & B[i + 7]);
					long u = ones ^ b;
					twosB = (ones & b) | (u & c);
					ones = u ^ c;
				}
				//CSA(foursB, twos, twos, twosA, twosB)
				{
					long u = twos ^ twosA;
					foursB = (twos & twosA) | (u & twosB);
					twos = u ^ twosB;
				}
				
				//CSA(eights, fours, fours, foursA, foursB)
				{
					long u = fours ^ foursA;
					eights = (fours & foursA) | (u & foursB);
					fours = u ^ foursB;
				}
				tot8 += Pop(eights);
			}
			
			
			if (i <= n - 4)
			{
				long twosA, twosB, foursA, eights;
				{
					long b = (A[i] & B[i]), c = (A[i + 1] & B[i + 1]);
					long u = ones ^ b;
					twosA = (ones & b) | (u & c);
					ones = u ^ c;
				}
				{
					long b = (A[i + 2] & B[i + 2]), c = (A[i + 3] & B[i + 3]);
					long u = ones ^ b;
					twosB = (ones & b) | (u & c);
					ones = u ^ c;
				}
				{
					long u = twos ^ twosA;
					foursA = (twos & twosA) | (u & twosB);
					twos = u ^ twosB;
				}
				eights = fours & foursA;
				fours = fours ^ foursA;
				
				tot8 += Pop(eights);
				i += 4;
			}
			
			if (i <= n - 2)
			{
				long b = (A[i] & B[i]), c = (A[i + 1] & B[i + 1]);
				long u = ones ^ b;
				long twosA = (ones & b) | (u & c);
				ones = u ^ c;
				
				long foursA = twos & twosA;
				twos = twos ^ twosA;
				
				long eights = fours & foursA;
				fours = fours ^ foursA;
				
				tot8 += Pop(eights);
				i += 2;
			}
			
			if (i < n)
			{
				tot += Pop((A[i] & B[i]));
			}
			
			tot += (Pop(fours) << 2) + (Pop(twos) << 1) + Pop(ones) + (tot8 << 3);
			
			return tot;
		}
		
		/// <summary>Returns the popcount or cardinality of the union of two sets.
		/// Neither array is modified.
		/// </summary>
		public static long Pop_union(long[] A, long[] B, int wordOffset, int numWords)
		{
			// generated from pop_array via sed 's/A\[\([^]]*\)\]/\(A[\1] \| B[\1]\)/g'
			int n = wordOffset + numWords;
			long tot = 0, tot8 = 0;
			long ones = 0, twos = 0, fours = 0;
			
			int i;
			for (i = wordOffset; i <= n - 8; i += 8)
			{
				/***  C macro from Hacker's Delight
				#define CSA(h,l, a,b,c) \
				{unsigned u = a ^ b; unsigned v = c; \
				h = (a & b) | (u & v); l = u ^ v;}
				***/
				
				long twosA, twosB, foursA, foursB, eights;
				
				// CSA(twosA, ones, ones, (A[i] | B[i]), (A[i+1] | B[i+1]))
				{
					long b = (A[i] | B[i]), c = (A[i + 1] | B[i + 1]);
					long u = ones ^ b;
					twosA = (ones & b) | (u & c);
					ones = u ^ c;
				}
				// CSA(twosB, ones, ones, (A[i+2] | B[i+2]), (A[i+3] | B[i+3]))
				{
					long b = (A[i + 2] | B[i + 2]), c = (A[i + 3] | B[i + 3]);
					long u = ones ^ b;
					twosB = (ones & b) | (u & c);
					ones = u ^ c;
				}
				//CSA(foursA, twos, twos, twosA, twosB)
				{
					long u = twos ^ twosA;
					foursA = (twos & twosA) | (u & twosB);
					twos = u ^ twosB;
				}
				//CSA(twosA, ones, ones, (A[i+4] | B[i+4]), (A[i+5] | B[i+5]))
				{
					long b = (A[i + 4] | B[i + 4]), c = (A[i + 5] | B[i + 5]);
					long u = ones ^ b;
					twosA = (ones & b) | (u & c);
					ones = u ^ c;
				}
				// CSA(twosB, ones, ones, (A[i+6] | B[i+6]), (A[i+7] | B[i+7]))
				{
					long b = (A[i + 6] | B[i + 6]), c = (A[i + 7] | B[i + 7]);
					long u = ones ^ b;
					twosB = (ones & b) | (u & c);
					ones = u ^ c;
				}
				//CSA(foursB, twos, twos, twosA, twosB)
				{
					long u = twos ^ twosA;
					foursB = (twos & twosA) | (u & twosB);
					twos = u ^ twosB;
				}
				
				//CSA(eights, fours, fours, foursA, foursB)
				{
					long u = fours ^ foursA;
					eights = (fours & foursA) | (u & foursB);
					fours = u ^ foursB;
				}
				tot8 += Pop(eights);
			}
			
			
			if (i <= n - 4)
			{
				long twosA, twosB, foursA, eights;
				{
					long b = (A[i] | B[i]), c = (A[i + 1] | B[i + 1]);
					long u = ones ^ b;
					twosA = (ones & b) | (u & c);
					ones = u ^ c;
				}
				{
					long b = (A[i + 2] | B[i + 2]), c = (A[i + 3] | B[i + 3]);
					long u = ones ^ b;
					twosB = (ones & b) | (u & c);
					ones = u ^ c;
				}
				{
					long u = twos ^ twosA;
					foursA = (twos & twosA) | (u & twosB);
					twos = u ^ twosB;
				}
				eights = fours & foursA;
				fours = fours ^ foursA;
				
				tot8 += Pop(eights);
				i += 4;
			}
			
			if (i <= n - 2)
			{
				long b = (A[i] | B[i]), c = (A[i + 1] | B[i + 1]);
				long u = ones ^ b;
				long twosA = (ones & b) | (u & c);
				ones = u ^ c;
				
				long foursA = twos & twosA;
				twos = twos ^ twosA;
				
				long eights = fours & foursA;
				fours = fours ^ foursA;
				
				tot8 += Pop(eights);
				i += 2;
			}
			
			if (i < n)
			{
				tot += Pop((A[i] | B[i]));
			}
			
			tot += (Pop(fours) << 2) + (Pop(twos) << 1) + Pop(ones) + (tot8 << 3);
			
			return tot;
		}
		
		/// <summary>Returns the popcount or cardinality of A &amp; ~B
		/// Neither array is modified.
		/// </summary>
		public static long Pop_andnot(long[] A, long[] B, int wordOffset, int numWords)
		{
			// generated from pop_array via sed 's/A\[\([^]]*\)\]/\(A[\1] \& ~B[\1]\)/g'
			int n = wordOffset + numWords;
			long tot = 0, tot8 = 0;
			long ones = 0, twos = 0, fours = 0;
			
			int i;
			for (i = wordOffset; i <= n - 8; i += 8)
			{
				/***  C macro from Hacker's Delight
				#define CSA(h,l, a,b,c) \
				{unsigned u = a ^ b; unsigned v = c; \
				h = (a & b) | (u & v); l = u ^ v;}
				***/
				
				long twosA, twosB, foursA, foursB, eights;
				
				// CSA(twosA, ones, ones, (A[i] & ~B[i]), (A[i+1] & ~B[i+1]))
				{
					long b = (A[i] & ~ B[i]), c = (A[i + 1] & ~ B[i + 1]);
					long u = ones ^ b;
					twosA = (ones & b) | (u & c);
					ones = u ^ c;
				}
				// CSA(twosB, ones, ones, (A[i+2] & ~B[i+2]), (A[i+3] & ~B[i+3]))
				{
					long b = (A[i + 2] & ~ B[i + 2]), c = (A[i + 3] & ~ B[i + 3]);
					long u = ones ^ b;
					twosB = (ones & b) | (u & c);
					ones = u ^ c;
				}
				//CSA(foursA, twos, twos, twosA, twosB)
				{
					long u = twos ^ twosA;
					foursA = (twos & twosA) | (u & twosB);
					twos = u ^ twosB;
				}
				//CSA(twosA, ones, ones, (A[i+4] & ~B[i+4]), (A[i+5] & ~B[i+5]))
				{
					long b = (A[i + 4] & ~ B[i + 4]), c = (A[i + 5] & ~ B[i + 5]);
					long u = ones ^ b;
					twosA = (ones & b) | (u & c);
					ones = u ^ c;
				}
				// CSA(twosB, ones, ones, (A[i+6] & ~B[i+6]), (A[i+7] & ~B[i+7]))
				{
					long b = (A[i + 6] & ~ B[i + 6]), c = (A[i + 7] & ~ B[i + 7]);
					long u = ones ^ b;
					twosB = (ones & b) | (u & c);
					ones = u ^ c;
				}
				//CSA(foursB, twos, twos, twosA, twosB)
				{
					long u = twos ^ twosA;
					foursB = (twos & twosA) | (u & twosB);
					twos = u ^ twosB;
				}
				
				//CSA(eights, fours, fours, foursA, foursB)
				{
					long u = fours ^ foursA;
					eights = (fours & foursA) | (u & foursB);
					fours = u ^ foursB;
				}
				tot8 += Pop(eights);
			}
			
			
			if (i <= n - 4)
			{
				long twosA, twosB, foursA, eights;
				{
					long b = (A[i] & ~ B[i]), c = (A[i + 1] & ~ B[i + 1]);
					long u = ones ^ b;
					twosA = (ones & b) | (u & c);
					ones = u ^ c;
				}
				{
					long b = (A[i + 2] & ~ B[i + 2]), c = (A[i + 3] & ~ B[i + 3]);
					long u = ones ^ b;
					twosB = (ones & b) | (u & c);
					ones = u ^ c;
				}
				{
					long u = twos ^ twosA;
					foursA = (twos & twosA) | (u & twosB);
					twos = u ^ twosB;
				}
				eights = fours & foursA;
				fours = fours ^ foursA;
				
				tot8 += Pop(eights);
				i += 4;
			}
			
			if (i <= n - 2)
			{
				long b = (A[i] & ~ B[i]), c = (A[i + 1] & ~ B[i + 1]);
				long u = ones ^ b;
				long twosA = (ones & b) | (u & c);
				ones = u ^ c;
				
				long foursA = twos & twosA;
				twos = twos ^ twosA;
				
				long eights = fours & foursA;
				fours = fours ^ foursA;
				
				tot8 += Pop(eights);
				i += 2;
			}
			
			if (i < n)
			{
				tot += Pop((A[i] & ~ B[i]));
			}
			
			tot += (Pop(fours) << 2) + (Pop(twos) << 1) + Pop(ones) + (tot8 << 3);
			
			return tot;
		}
		
		public static long Pop_xor(long[] A, long[] B, int wordOffset, int numWords)
		{
			int n = wordOffset + numWords;
			long tot = 0, tot8 = 0;
			long ones = 0, twos = 0, fours = 0;
			
			int i;
			for (i = wordOffset; i <= n - 8; i += 8)
			{
				/***  C macro from Hacker's Delight
				#define CSA(h,l, a,b,c) \
				{unsigned u = a ^ b; unsigned v = c; \
				h = (a & b) | (u & v); l = u ^ v;}
				***/
				
				long twosA, twosB, foursA, foursB, eights;
				
				// CSA(twosA, ones, ones, (A[i] ^ B[i]), (A[i+1] ^ B[i+1]))
				{
					long b = (A[i] ^ B[i]), c = (A[i + 1] ^ B[i + 1]);
					long u = ones ^ b;
					twosA = (ones & b) | (u & c);
					ones = u ^ c;
				}
				// CSA(twosB, ones, ones, (A[i+2] ^ B[i+2]), (A[i+3] ^ B[i+3]))
				{
					long b = (A[i + 2] ^ B[i + 2]), c = (A[i + 3] ^ B[i + 3]);
					long u = ones ^ b;
					twosB = (ones & b) | (u & c);
					ones = u ^ c;
				}
				//CSA(foursA, twos, twos, twosA, twosB)
				{
					long u = twos ^ twosA;
					foursA = (twos & twosA) | (u & twosB);
					twos = u ^ twosB;
				}
				//CSA(twosA, ones, ones, (A[i+4] ^ B[i+4]), (A[i+5] ^ B[i+5]))
				{
					long b = (A[i + 4] ^ B[i + 4]), c = (A[i + 5] ^ B[i + 5]);
					long u = ones ^ b;
					twosA = (ones & b) | (u & c);
					ones = u ^ c;
				}
				// CSA(twosB, ones, ones, (A[i+6] ^ B[i+6]), (A[i+7] ^ B[i+7]))
				{
					long b = (A[i + 6] ^ B[i + 6]), c = (A[i + 7] ^ B[i + 7]);
					long u = ones ^ b;
					twosB = (ones & b) | (u & c);
					ones = u ^ c;
				}
				//CSA(foursB, twos, twos, twosA, twosB)
				{
					long u = twos ^ twosA;
					foursB = (twos & twosA) | (u & twosB);
					twos = u ^ twosB;
				}
				
				//CSA(eights, fours, fours, foursA, foursB)
				{
					long u = fours ^ foursA;
					eights = (fours & foursA) | (u & foursB);
					fours = u ^ foursB;
				}
				tot8 += Pop(eights);
			}
			
			
			if (i <= n - 4)
			{
				long twosA, twosB, foursA, eights;
				{
					long b = (A[i] ^ B[i]), c = (A[i + 1] ^ B[i + 1]);
					long u = ones ^ b;
					twosA = (ones & b) | (u & c);
					ones = u ^ c;
				}
				{
					long b = (A[i + 2] ^ B[i + 2]), c = (A[i + 3] ^ B[i + 3]);
					long u = ones ^ b;
					twosB = (ones & b) | (u & c);
					ones = u ^ c;
				}
				{
					long u = twos ^ twosA;
					foursA = (twos & twosA) | (u & twosB);
					twos = u ^ twosB;
				}
				eights = fours & foursA;
				fours = fours ^ foursA;
				
				tot8 += Pop(eights);
				i += 4;
			}
			
			if (i <= n - 2)
			{
				long b = (A[i] ^ B[i]), c = (A[i + 1] ^ B[i + 1]);
				long u = ones ^ b;
				long twosA = (ones & b) | (u & c);
				ones = u ^ c;
				
				long foursA = twos & twosA;
				twos = twos ^ twosA;
				
				long eights = fours & foursA;
				fours = fours ^ foursA;
				
				tot8 += Pop(eights);
				i += 2;
			}
			
			if (i < n)
			{
				tot += Pop((A[i] ^ B[i]));
			}
			
			tot += (Pop(fours) << 2) + (Pop(twos) << 1) + Pop(ones) + (tot8 << 3);
			
			return tot;
		}
		
		/* python code to generate ntzTable
		def ntz(val):
		if val==0: return 8
		i=0
		while (val&0x01)==0:
		i = i+1
		val >>= 1
		return i
		print ','.join([ str(ntz(i)) for i in range(256) ])
		***/
		/// <summary>table of number of trailing zeros in a byte </summary>
		public static readonly sbyte[] ntzTable = new sbyte[]{8, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0, 4, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0, 5, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0, 4, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0, 6, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0, 4, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0, 5, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0, 4, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0, 7, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0, 4, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0, 5, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0, 4, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0, 6, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0, 4, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0, 5, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0, 4, 0, 1, 0, 2, 0, 1, 0, 3, 0, 1, 0, 2, 0, 1, 0};
		
		
		/// <summary>Returns number of trailing zeros in a 64 bit long value. </summary>
		public static int Ntz(long val)
		{
			// A full binary search to determine the low byte was slower than
			// a linear search for nextSetBit().  This is most likely because
			// the implementation of nextSetBit() shifts bits to the right, increasing
			// the probability that the first non-zero byte is in the rhs.
			//
			// This implementation does a single binary search at the top level only
			// so that all other bit shifting can be done on ints instead of longs to
			// remain friendly to 32 bit architectures.  In addition, the case of a
			// non-zero first byte is checked for first because it is the most common
			// in dense bit arrays.
			
			int lower = (int) val;
			int lowByte = lower & 0xff;
			if (lowByte != 0)
				return ntzTable[lowByte];
			
			if (lower != 0)
			{
				lowByte = (SupportClass.Number.URShift(lower, 8)) & 0xff;
				if (lowByte != 0)
					return ntzTable[lowByte] + 8;
				lowByte = (SupportClass.Number.URShift(lower, 16)) & 0xff;
				if (lowByte != 0)
					return ntzTable[lowByte] + 16;
				// no need to mask off low byte for the last byte in the 32 bit word
				// no need to check for zero on the last byte either.
				return ntzTable[SupportClass.Number.URShift(lower, 24)] + 24;
			}
			else
			{
				// grab upper 32 bits
				int upper = (int) (val >> 32);
				lowByte = upper & 0xff;
				if (lowByte != 0)
					return ntzTable[lowByte] + 32;
				lowByte = (SupportClass.Number.URShift(upper, 8)) & 0xff;
				if (lowByte != 0)
					return ntzTable[lowByte] + 40;
				lowByte = (SupportClass.Number.URShift(upper, 16)) & 0xff;
				if (lowByte != 0)
					return ntzTable[lowByte] + 48;
				// no need to mask off low byte for the last byte in the 32 bit word
				// no need to check for zero on the last byte either.
				return ntzTable[SupportClass.Number.URShift(upper, 24)] + 56;
			}
		}
		
		/// <summary>Returns number of trailing zeros in a 32 bit int value. </summary>
		public static int Ntz(int val)
		{
			// This implementation does a single binary search at the top level only.
			// In addition, the case of a non-zero first byte is checked for first
			// because it is the most common in dense bit arrays.
			
			int lowByte = val & 0xff;
			if (lowByte != 0)
				return ntzTable[lowByte];
			lowByte = (SupportClass.Number.URShift(val, 8)) & 0xff;
			if (lowByte != 0)
				return ntzTable[lowByte] + 8;
			lowByte = (SupportClass.Number.URShift(val, 16)) & 0xff;
			if (lowByte != 0)
				return ntzTable[lowByte] + 16;
			// no need to mask off low byte for the last byte.
			// no need to check for zero on the last byte either.
			return ntzTable[SupportClass.Number.URShift(val, 24)] + 24;
		}
		
		/// <summary>returns 0 based index of first set bit
		/// (only works for x!=0)
		/// <br/> This is an alternate implementation of ntz()
		/// </summary>
		public static int Ntz2(long x)
		{
			int n = 0;
			int y = (int) x;
			if (y == 0)
			{
				n += 32; y = (int) (SupportClass.Number.URShift(x, 32));
			} // the only 64 bit shift necessary
			if ((y & 0x0000FFFF) == 0)
			{
				n += 16; y = SupportClass.Number.URShift(y, 16);
			}
			if ((y & 0x000000FF) == 0)
			{
				n += 8; y = SupportClass.Number.URShift(y, 8);
			}
			return (ntzTable[y & 0xff]) + n;
		}
		
		/// <summary>returns 0 based index of first set bit
		/// <br/> This is an alternate implementation of ntz()
		/// </summary>
		public static int Ntz3(long x)
		{
			// another implementation taken from Hackers Delight, extended to 64 bits
			// and converted to Java.
			// Many 32 bit ntz algorithms are at http://www.hackersdelight.org/HDcode/ntz.cc
			int n = 1;
			
			// do the first step as a long, all others as ints.
			int y = (int) x;
			if (y == 0)
			{
				n += 32; y = (int) (SupportClass.Number.URShift(x, 32));
			}
			if ((y & 0x0000FFFF) == 0)
			{
				n += 16; y = SupportClass.Number.URShift(y, 16);
			}
			if ((y & 0x000000FF) == 0)
			{
				n += 8; y = SupportClass.Number.URShift(y, 8);
			}
			if ((y & 0x0000000F) == 0)
			{
				n += 4; y = SupportClass.Number.URShift(y, 4);
			}
			if ((y & 0x00000003) == 0)
			{
				n += 2; y = SupportClass.Number.URShift(y, 2);
			}
			return n - (y & 1);
		}
		
		
		/// <summary>returns true if v is a power of two or zero</summary>
		public static bool IsPowerOfTwo(int v)
		{
			return ((v & (v - 1)) == 0);
		}
		
		/// <summary>returns true if v is a power of two or zero</summary>
		public static bool IsPowerOfTwo(long v)
		{
			return ((v & (v - 1)) == 0);
		}
		
		/// <summary>returns the next highest power of two, or the current value if it's already a power of two or zero</summary>
		public static int NextHighestPowerOfTwo(int v)
		{
			v--;
			v |= v >> 1;
			v |= v >> 2;
			v |= v >> 4;
			v |= v >> 8;
			v |= v >> 16;
			v++;
			return v;
		}
		
		/// <summary>returns the next highest power of two, or the current value if it's already a power of two or zero</summary>
		public static long NextHighestPowerOfTwo(long v)
		{
			v--;
			v |= v >> 1;
			v |= v >> 2;
			v |= v >> 4;
			v |= v >> 8;
			v |= v >> 16;
			v |= v >> 32;
			v++;
			return v;
		}
	}
}